基于孔压静力触探试验的水运工程土分类方法研究

土的工程分类是工程勘察和设计应用的关键问题之一。基于孔压静力触探测试（piezocone penetration test,简称CPTU）原位测试参数进行土分类是高效实用的方法。国内外现有分类方法的名称及标准与我国《水运工程岩土勘察规范》（JTS 133－2013）不符合。因此,建立基于CPTU原位测试参数、符合我国行业标准的土工程分类方法具有重要工程意义。在收集大量国内外水运工程CPTU测试资料的基础上,对比分析了616个间距小于5 m的CPTU测试孔和相应钻孔取样与室内土工试验成果。选择国内外7种常用的CPTU土分类图进行应用比较,发现这些土分类图所采用的应力修正计算方法在考虑浅层土体的有效上覆应力修正时存在一定的缺陷,通过引入新的应力修正方法和修正土分类边界线,建立了适合我国水运工程的CPTU土分类方法。对比应用分析表明,该分类图能够准确地进行水运工程土类划分,尤其适合于软土、粉细砂和中粗砂的划分,可作为我国水运工程的土工程分类方法。     

长江中下游水阳江流域BZK0402孔多重地层划分及其冰后期海平面变化的沉积响应

[研究目的]开展水阳江流域标准孔BZK0402孔多重地层划分,探讨长江支流水阳江流域冰后期海平面变化的沉积响应以及古丹阳湖的成因和形成时代.[研究方法]以岩石地层为基础,在磁性地层和年代地层的双重约束下,对BZK0402孔进行多重地层划分.对比分析BZK0402孔和长江河谷、长江三角洲等邻区钻孔.[研究结果]BZK04...     

地质钻探垂钻定向纠偏控制的工程实现与实验分析

理论提出的纠偏方法需反复进行实验验证方可应用于实际工程,然而垂钻纠偏控制过程复杂,操作难度大,所需时间长、资金庞大,直接将所提方法放置现场调试是不可取的,而仅采用计算机仿真对算法进行验证也有一定局限性,因此发展和研究纠偏控制工程实现方法十分必要。本文以地质钻探钻进过程定向纠偏控制的工程实现为导向,首先分析并给出实际纠偏工艺过程以及纠偏控制的特点与目标;然后总结基于模型预测控制的纠偏控制问题与优化目标,结合笔者早期的一些纠偏控制理论研究,分别阐述不同纠偏工况下的纠偏控制方法;其次开发定向纠偏控制系统,用于集成纠偏控制算法,使得算法能够应用于实际工程;最后设计纠偏控制实验,以验证纠偏控制算法的工程适用性。实验表明,所提纠偏控制方法能够有效应用于实际纠偏过程,并应对和完成多种纠偏任务。     

沉积型一水硬铝石型铝土矿床勘查评价中 几个问题的探讨—以黔北铝土矿床为例

以黔北铝土矿为例,对沉积型一水硬铝石型铝土矿勘查评价中的4个问题进行讨论,并提出:(1)将勘查类型按普查、详查、勘探阶段分别用初定、暂定、确定来进行定性;(2)用"菱形孔"而非"矩形孔"的布置方法来解决勘查类型的变更与工程控制间距非整倍数的问题;(3)"地表工程间距加密一倍"的适用范围是:露采且处于"剥蚀区"内的矿体。地表露头线呈线状展布且上覆有岩层或虽也强风化,但仍保存原岩层层理迹象的范围,则可与勘查类型和勘查阶段同距同网;(4)普查、详查阶段中工程矿体边界A/S的取值可在1.8～2.6之间,以保证块段矿体中的A/S值达到工业要求即可。     

东昆仑祁漫塔格小圆山地区辉长辉绿岩年龄、地球化学特征及对区域构造演化的约束

通过东昆仑祁漫塔格小圆山辉长辉绿岩岩相学、年代学和岩石地球化学研究, 探讨其岩浆作用及其源区、成岩构造环境、年龄及地质意义。结果表明, 辉长辉绿岩为拉斑玄武岩系列岩石, SiO2含量为48.27%~50.06%, 全碱Na2O+K2O含量低, 为3.10%~4.04%, 且钠较钾富, MgO含量为7.81%~8.60%, TFe2O3含量为10.69%~12.00%, TiO2含量为1.32%~1.76%;∑REE平均为58.13×10-6, δEu值为1.02~1.24, 平均为1.12, 呈轻微正异常; 稀土元素球粒陨石标准化配分模式图上呈Gd略亏损的近平坦曲线, 具有轻、重稀土元素分异不明显的轻稀土元素弱富集特征; 岩石明显富集大离子亲石元素Cs、Rb、Ba、K、Sr, 活泼的不相容元素U和Th, 轻稀土元素及Pb, 相对亏损高场强元素Nb、Ta和P。采用SIMS锆石U-Pb定年方法, 获得小圆山辉长辉绿岩的年龄加权平均值为415±16 Ma (MSWD=5.0)和243±11 Ma (MSWD=4.1), 前者代表辉长辉绿岩的结晶年龄, 后者应代表晚期深部岩浆上升侵位到辉长辉绿岩中形成的锆石结晶年龄, 是对中三叠世末期伸展活动的响应。结合岩石地球化学、构造特征和区域地质背景, 认为小圆山辉长辉绿岩是拉张型岛弧背景下亏损的岩石圈地幔平衡部分熔融的产物, 受到一定程度地壳物质的混染。     

改进切线模量的非线性弹性模型

为了更好的反映基坑开挖后土体的变形非线性特性,采用幂函数描述土体剪切过程中切线模量随主应力差值增大而衰减的过程。积分得到主应力差值和应变的数学表达式,其反映的数学规律符合一般土力学模型的要求。对应于不同的幂指数,该表达式可以很好拟合三轴试验应力-应变曲线。基于Duncan-Chang模型参数确定的方法,提出了本文模型参数的确定方法。在通用有限元软件基础上二次开发了模型的计算程序。应用于某基坑变形的计算结果表明,本文提出的模型比Duncan-Chang模型能更好的预测围护结构的变形。     

公路工程项目管理模式设计—施工总承包的优势

通过不同管理模式的公路工程项目建设经验,分析传统公路工程项目管理模式得与失以及设计—施工总承包的优势,更好地保证设计与施工质量,有效控制造价,推进公路勘察设计与施工企业间战略重组,增强国际竞争力。     

A new understanding of Demala Group complex in Chayu Area,southeastern Qinghai-Tibet Plateau: Evidence from zircon U-Pb and mica 40Ar/39Ar dating

The Chayu area is located at the southeastern margin of the Qinghai-Tibet Plateau. This region was considered to be in the southeastward extension of the Lhasa Block, bounded by Nujiang suture zone in the north and Yarlung Zangbo suture zone in the south. The Demala Group complex, a set of high-grade metamorphic gneisses widely distributed in the Chayu area, is known as the Precambrian metamorphic basement of the Lhasa Block in the area. According to field-based investigations and microstructure analysis, the Demala Group complex is considered to mainly consist of banded biotite plagiogneisses, biotite quartzofeldspathic gneiss, granitic gneiss, amphibolite, mica schist, and quartz schist, with many leucogranite veins. The zircon U-Pb ages of two granitic gneiss samples are 205 ± 1 Ma and 218 ± 1 Ma, respectively, representing the ages of their protoliths. The zircons from two biotite plagiogneisses samples show core-rim structures. The U-Pb ages of the cores are mainly 644 –446 Ma, 1213 –865 Ma, and 1780 –1400 Ma, reflecting the age characteristics of clastic zircons during sedimentation of the original rocks. The U-Pb ages of the rims are from 203 ± 2 Ma to 190 ± 1 Ma, which represent the age of metamorphism. The zircon U-Pb ages of one sample taken from the leucogranite veins that cut through granitic gneiss foliation range from 24 Ma to 22 Ma, interpreted as the age of the anatexis in the Demala Group complex. Biotite and muscovite separates were selected from the granitic gneiss, banded gneiss, and leucogranite veins for ⁴⁰Ar/³⁹Ar dating. The plateau ages of three muscovite samples are 16.56 ± 0.21 Ma, 16.90 ± 0.21 Ma, and 23.40 ± 0.31 Ma, and the plateau ages of four biotite samples are 16.70 ± 0.24 Ma, 16.14 ± 0.19 Ma, 15.88 ± 0.20 Ma, and 14.39 ± 0.20 Ma. The mica Ar-Ar ages can reveal the exhumation and cooling history of the Demala Group complex. Combined with the previous research results of the Demala Group complex, the authors refer that the Demala Group complex should be a set of metamorphic complex. The complex includes not only Precambrian basement metamorphic rock series, but also Paleozoic sedimentary rock and Mesozoic granitic rock. Based on the deformation characteristics, the authors concluded that two stages of the metamorphism and deformation can be revealed in the Demala Group complex since the Mesozoic, namely Late Triassic-Early Jurassic (203 –190 Ma) and Oligocene –Miocene (24 –14 Ma). The early stage of metamorphism (ranging from 203 –190 Ma) was related to the Late Triassic tectono-magmatism in the area. The anatexis and uplifting-exhumation of the later stage (24 –14 Ma) were related to the shearing of the Jiali strike-slip fault zone. The Miocene structures are response to the large-scale southeastward escape of crustal materials and block rotation in Southeast Tibet after India-Eurasia collision.©2021 China Geology Editorial Office.     

Archean (about 2500 Ma) anatexis in eastern North China Block

Two Neoarchean alkaline feldspar-rich granites sourced from partially melted granulite-facies granodioritic orthogneiss have been here recognised in the eastern part of the North China Block (NCB). These poorly foliated granites have previously been assumed to be Mesozoic in age and never dated, and so their significance has not been recognised until now. The first granite (AG1) is a porphyritic syenogranite with megacrystic K-feldspar, and the second (AG2) is a quartz syenite with perthitic megacryst. Zircons from the granites yield LA-ICP-MS U-Pb ages of 2499 ± 10 Ma (AG1), and 2492 ± 28 Ma (AG2), which are slightly younger than the granodioritic orthogneiss that they intrude with a crystallisation U-Pb age of 2537 ± 34 Ma. The younger granites have higher assays for SiO₂ (71.91% for AG1 and 73.22% for AG2) and K₂O (7.52% for AG1 and 8.37% for AG2), and much lower assays for their other major element than the granodioritic orthogneiss. All of the granodioritic orthogneiss and granite samples have similar trace element patterns, with depletion in Th, U, Nb, and Ti and enrichment in Rb, Ba, K, La, Ce, and P. This indicates that the granites are derived from the orthogneiss as partial melts. Although they exhibit a similar REE pattern, the granites have much lower total REE contents (30.97×10⁻⁶ for AG1, and 25.93×10⁻⁶ for AG2), but pronounced positive Eu anomalies (Eu/Eu* = 8.57 for AG1 and 27.04 for AG2). The granodioritic orthogneiss has an initial ⁸⁷Sr/⁸⁶Sr ratio of 0.70144, εNd(t) value of 3.5, and εHf(t) values ranging from −3.2 to +2.9. The orthogneiss is a product of fractional crystallisation from a dioritic magma, which was derived from a mantle source contaminated by melts derived from a felsic slab. By contrast, the AG1 sample has an initial ⁸⁷Sr/⁸⁶Sr ratio of 0.6926 that is considered too low in value, εNd(t) value of 0.3, and εHf(t) values between +0.57 and +3.82; whereas the AG2 sample has an initial ⁸⁷Sr/⁸⁶Sr ratio of 0.70152, εNd(t) value of 1.3, and εHf(t) values between +0.5 and +14.08. These assays indicate that a Sr-Nd-Hf isotopic disequilibrium exists between the granite and granodioritic orthogneiss. The elevated εHf(t) values of the granites can be explained by the involvement of Hf-bearing minerals, such as orthopyroxene, amphibole, and biotite, in anatectic reactions in the granodioritic orthogneiss. Based on the transitional relationship between the granites and granodioritic orthogneiss and the geochemical characteristics mentioned above, it is concluded that the granites are the product of rapid partial-melting of the granodioritic orthogneiss after granulite-facies metamorphism, and their crystallisation age of about 2500 Ma provides the minimum age of the metamorphism. This about 2500 Ma tectonic-metamorphic event in NCB is similar to the other cratons in India, Antarctica, northern and southern Australia, indicating a possible connection between these cratons during the Neoarchean.     

Hydrothermal alteration processes in the giant Dahutang tungsten deposit,South China: Implications from litho-geochemistry and mass balance calculation

The giant Dahutang tungsten (W) deposit has a total reserve of more than 1.31 Mt WO₃. Veinlet-disseminated scheelite and vein type wolframite mineralization are developed in this deposit, which are related to Late Mesozoic biotite granite. Four major types of alterations, which include albitization, potassic-alteration, and greisenization, and overprinted silicification developed in contact zone. The mass balance calculate of the four alteration types were used to further understanding of the mineralization process. The fresh porphyritic biotite granite has high Nb, Ta, and W, but low Ca and Sr while the Jiuling granodiorite has high Ca and Sr, but low Nb, Ta, and W concentrations. The altered porphyritic biotite granite indicated that the Nb, Ta, and W were leached out from the fresh porphyritic biotite granite, especially by sodic alteration. The low Ca and Sr contents of the altered Neoproterozoic Jiuling granodiorite indicate that Ca and Sr had been leached out from the fresh granodiorite by the fluid from Mesozoic porphyritic biotite granites. The metal W of the Dahutang deposit was mainly derived from the fluid exsolution from the melt and alteration of W-bearing granites. This study of alteration presents a new hydrothermal circulation model to understand tungsten mineralization in the Dahutang deposit.